TWM575224U - Photovoltaic car roof - Google Patents

Abstract

The present invention provides a photovoltaic power generation roof comprising: a structural layer comprising a flat-plate or single-curved power generation zone and a transition zone disposed around the power generation zone; and a photovoltaic component layer including A flexible photovoltaic film assembly secured to an upper surface of the power generation zone. The novel adopts a single curved surface or a flat shaped power generation area, and only needs to lay the flexible photovoltaic film component on the power generation area, the processing process is simple and convenient, and since it does not generate complicated stress, the photovoltaic power generation can be effectively extended. The service life of the roof.

Description

Photovoltaic roof [ Cross-reference to related applications ]

The present application claims priority to Chinese Patent Application No. 201720783912.X and No. 201720782850.0, filed on June 30, 2017, the entire contents of

The present invention relates to the field of solar power generation technology, and in particular to a photovoltaic power generation roof capable of generating electrical energy under illumination.

Solar cars are formed by placing solar elements on the roof, so that in the case of illumination, the solar elements can provide power to the energy storage system of the car. At present, the way to install solar components on the roof is usually installed by mounting the fixture on the roof and then mounting the solar components on the fixture; or by laminating the solar components with the roof. Roof; both installations enable successful installation of solar modules on the roof.

However, if the installation is carried out by means of a mounting bracket, it is necessary to make a corresponding fixing bracket, and then assemble the fixing bracket with the roof and the components. This mounting method requires many parts and is cumbersome; if lamination is used To make an integrated roof, it is necessary to laminate the roof and solar components after the roof is stamped, and the lamination process takes a long time.

In order to at least partially solve the technical problems existing in the prior art, the present invention provides a photovoltaic power generation roof which can save time, is simple and reliable to install.

According to an aspect of the present invention, a photovoltaic power generation roof is provided, comprising: a structural layer including a flat-plate or single-curved power generation region and a transition region disposed around the power generation region; and a photovoltaic component layer A flexible photovoltaic film assembly is included that is secured to an upper surface of the power generation zone.

The power generation zone may be in the shape of a flat plate, and the transition zone includes two first transition zones respectively connected to opposite sides of the power generation zone and two second transition zones respectively connected to the other two sides of the power generation zone; The first transition zone and the second transition zone are all single-curved, and the bus bars of the first transition zone and the second transition zone are both parallel to the edge of the corresponding power generation zone, and the first transition zone and the second transition The lower surface of the zone is adapted to the upper surface of the roof.

The power generation zone may be a single curved shape, and the transition zone includes two first transition zones respectively connected to two curved edges of the power generation zone and respectively connected to two straight edges of the power generation zone Two second transition regions; the first transition region has a hyperboloid shape, and an upper edge of one side of the first transition region is tangent to and connected to the power generation region, and a lower surface of the first transition region is The upper surface of the roof is adapted; the second transition zone has a single curved shape, and an upper edge of one side of the second transition zone is tangent to and connected to the power generating zone, and the second transition zone The lower surface is adapted to the upper surface of the roof.

The bus bar of the power generation zone may be perpendicular to the front and rear direction of the roof.

The bus bars of the power generation zone may be parallel to the front and rear directions of the roof.

The power generation area may be provided with a through hole or a groove, and a junction box of the flexible photovoltaic film assembly is disposed in the through hole or the groove, and an edge of the junction box and the through hole or the groove Sealed connection.

The depth of the groove may be the same as the thickness of the junction box.

The flexible photovoltaic film assembly can be sealingly coupled to the power generation zone.

The power generation zone may be a single curved shape, and the transition zone includes two first transition zones respectively connected to two curved edges of the power generation zone and respectively connected to two straight edges of the power generation zone Two second transition regions; the first transition region has a single curved shape, and an upper edge of one side of the first transition region is tangent to and connected to the power generating region, and a lower surface of the first transition region Compatible with an upper surface of the roof; the second transition zone has a single curved shape, and an upper edge of one side of the second transition zone is tangent to and connected to the power generating zone, the second transition zone The lower surface is adapted to the upper surface of the roof.

The power generation zone may be a groove bottom surface of a groove disposed in a middle portion of the structural layer.

The upper surface of the flexible photovoltaic film assembly can smoothly transition with the upper surface of the transition zone.

The bottom surface of the groove may be a flat plate shape, and the transition region includes two first transition regions respectively corresponding to opposite sides of the bottom surface of the groove and two second transition regions respectively corresponding to two other sides of the bottom surface of the groove The first transition zone and the second transition zone are all in a single curved shape, and the bus bars of the first transition zone and the second transition zone are parallel to the corresponding edges of the bottom surface of the groove.

The bottom surface of the groove may be a single curved surface, and the transition region includes two first transition regions respectively corresponding to two curved edges of the bottom surface of the groove and two straight lines respectively corresponding to the bottom surface of the groove Two second transition regions disposed at an edge; the first transition region having a hyperboloid shape, an upper edge of one side of the first transition region being parallel to an arcuate edge of the bottom surface of the groove; the second transition The zone has a single curved shape, and the busbar of the second transition zone is parallel to the generatrix of the bottom surface of the groove.

The bus bar of the bottom surface of the groove may be parallel to the front and rear direction of the roof.

The bus bar of the bottom surface of the groove may be perpendicular to the front and rear direction of the roof.

The bottom surface of the groove may be provided with a through hole or a sinking groove, and a junction box of the flexible photovoltaic film assembly is disposed in the through hole or the sinking groove.

The distance between the flexible photovoltaic film component and the side of the groove may be no more than 10 mm.

The flexible photovoltaic film assembly is sealingly coupled to the bottom surface or side of the groove at least at an edge, and the flexible photovoltaic film assembly and the side of the groove are filled with a sealing material.

The groove may be a through groove, and both ends of the through slot opening are connected to the vehicle body, and the closed sides of the through slot are connected with the transition zone; the bottom surface of the through slot is a planar shape or a single curved shape.

1‧‧‧Flexible Photovoltaic Modules

2‧‧‧First transition zone

3‧‧‧Second transition zone

4‧‧‧Power generation area

1 is a schematic structural view showing a photovoltaic power generation roof according to a first exemplary embodiment of the present invention; FIG. 2 is a cross-sectional view taken along line AA of FIG. 1; and FIG. 3 is taken along line BB of FIG. FIG. 4 is a schematic structural view showing a photovoltaic power generation roof according to a second exemplary embodiment of the present invention; FIG. 5 is a cross-sectional view taken along line CC of FIG. 4; and FIG. 6 is a line DD along FIG. A cross-sectional view taken; FIG. 7 is a schematic structural view showing a photovoltaic power generation roof according to a sixth exemplary embodiment of the present invention; 8 is a cross-sectional view taken along line EE of FIG. 7; FIG. 9 is a cross-sectional view taken along line FF of FIG. 7; and FIG. 10 is a view showing a structure of a photovoltaic power generation roof according to a seventh exemplary embodiment of the present invention. Fig. 11 is a cross-sectional view taken along line GG in Fig. 10; and Fig. 12 is a cross-sectional view taken along line HH in Fig. 10.

The present invention will be further described below in conjunction with the accompanying drawings. The embodiments described below with reference to the accompanying drawings are intended to be illustrative only, and are not to be construed as limiting.

In the present invention, the front refers to the direction of the front of the vehicle, and the rear refers to the direction of the rear, and the left and right refer to the left and right sides facing the front of the vehicle and facing away from the rear.

In the present invention, a single curved surface refers to a curved surface formed by a straight line segment as a track in which a bus bar slides along a curved segment, and a hyperbolic surface refers to a curved surface formed as a curved surface of a bus bar sliding along another curved segment; For a surface, the bus should be perpendicular to the plane of the curve segment; for a hyperboloid, the plane of the bus should be perpendicular to the plane of the other curve segment.

In the present invention, a groove means that the surface of the material in one region is lower than the surface of the material outside the region, and the material of the region is joined to the material outside the region, for example by stamping a plate-like member. A sinking groove means that the surface of a material in an area is lower than the surface of the material outside the area, and the material outside the area forms an enclosed structure. The through groove means that the surface of the material in one region is lower than the surface of the material outside the region, and the material outside the region is distributed on opposite sides of the region, for example, a U-shaped through groove.

First exemplary embodiment

As shown in FIG. 1 to FIG. 3, the exemplary embodiment provides a photovoltaic power generation roof including a structural layer in which a central portion of the structural layer is a single-curved power generation region 4, and a bus bar of the power generation region 4 extends in a left-right direction. The busbar moves along a trajectory curve extending in the front-rear direction to form a single curved surface of the power generating zone 4. The periphery of the power generation area 4 is a transition zone, and the transition zone is a closed structure. The transition zone includes two second transition zones (or transition bars) 3 on the front and rear sides of the power generation zone 4, and a trajectory curve of the second transition zone 3 The segments extend in the front-rear direction, and the bus bars of the second transition region 3 are parallel to the bus bars of the power generating region 4. The transition zone further includes two first transition zones 2 on the left and right sides of the power generation zone 4, the busbars of the first transition zone 2 are parallel to the busbars of the power generation zone 4, the trajectory curve segments of the first transition zone 2 and the trajectory of the power generation zone 4 The curve segments are parallel.

Specifically, in the present exemplary embodiment, the power generation area 4 is a single curved shape, and the two first transition areas 2 are respectively connected to the two curved edges of the power generation area 4, and the two second transition areas 3 are respectively The two straight edges of the power generation zone 4 are connected. The first transition zone 2 has a single curved shape, the upper edge of one side of the first transition zone 2 is tangential and connected to the power generating zone 4, and the lower surface of the first transition zone 2 is adapted to the upper surface of the roof. The second transition zone 3 has a single curved shape, the upper edge of one side of the second transition zone 3 is tangential and connected to the power generating zone 4, and the lower surface of the second transition zone 3 is adapted to the upper surface of the roof.

In the present exemplary embodiment, a smooth transition connection between the first transition zone 2 and the second transition zone 3, between the first transition zone 2 and the second transition zone 3, and between the first transition zone 2 and the second transition zone 3 The connection between the power generation area 4 and the power generation area 4 may be connected by welding, bonding, riveting, and bolting, or may be formed by integral molding such as stamping or casting.

On the power generation area 4, a flexible photovoltaic film assembly 1 is directly laid, and the flexible photovoltaic film assembly 1 and the power generation area 4 can be connected by welding, bonding, riveting, etc., and can also be fixed by pressing the strip.

Since the power generating region 4 in the embodiment has a single curved shape, the flexible photovoltaic film module 1 can be directly laid on the power generating region 4, so that after the laying is completed, the flexible photovoltaic film module 1 is bent only in a single direction, and will not Produces three-way stress, thus reducing installation to a certain extent Difficulty can also significantly improve the installation effect and extend the service life.

In order to ensure that the roof can maintain a smooth shape after the installation of the solar component, a sinking groove is machined in the power generating zone 4, and the junction box of the flexible photovoltaic film module 1 is installed in the sinking groove; in order to ensure the flexible photovoltaic film component 1 The flatness is preferably processed to the same depth as the junction box. Of course, the manner of installing the junction box in the present exemplary embodiment is also applicable to the following second to fifth exemplary embodiments.

Second exemplary embodiment

As shown in FIG. 4 to FIG. 6 , the exemplary embodiment provides a photovoltaic power generation roof including a structural layer, a middle portion of the structural layer is a power generation area 4, and a power generation area 4 is surrounded by a transition structure of a enclosed structure; 4 is a single curved shape, the bus bar of the power generation zone 4 extends in the front-rear direction, and the trajectory curve of the bus bar of the power generation zone 4 extends in the left-right direction. The transition zone includes two first transition zones 2 on the front and rear sides of the power generation zone 4, respectively. The first transition zone 2 has a single curved shape, and the busbar of the first transition zone 2 is parallel to the busbar of the power generation zone 4, and the first transition The plane of the trajectory curve of the busbar of zone 2 is parallel to the plane of the trajectory curve of the busbar of the power generation zone 4. The transition zone further includes two second transition zones 3 on the left and right sides of the power generation zone 4, the second transition zone 3 is a single curved shape, the busbar of the second transition zone 3 is parallel to the busbar of the power generation zone 4, and the second The trajectory curve of the busbar of the transition zone 3 is tangent to the trajectory curve of the power generation zone 4.

Specifically, in the present exemplary embodiment, the power generation area 4 is a single curved shape, and the two first transition areas 2 are respectively connected to the two curved edges of the power generation area 4, and the two second transition areas 3 are respectively The two straight edges of the power generation zone 4 are connected. The upper edge of one side of the first transition zone 2 is tangential and connected to the power generating zone 4, and the lower surface of the first transition zone 2 is adapted to the upper surface of the roof. The upper edge of one side of the second transition zone 3 is tangential and connected to the power generating zone 4, and the lower surface of the second transition zone 3 is adapted to the upper surface of the roof.

In the present exemplary embodiment, a smooth transition connection between the first transition zone 2 and the second transition zone 3, between the first transition zone 2 and the second transition zone 3, and between the first transition zone 2 and the second transition zone 3 And hair The connection between the electric regions 4 can be connected by means of welding, bonding, riveting and bolting, or can be formed by integral molding such as stamping or casting.

On the power generation area 4, a flexible photovoltaic film assembly 1 is directly laid, and the flexible photovoltaic film assembly 1 and the power generation area 4 can be connected by welding, bonding, riveting, etc., and can also be fixed by pressing the strip.

Since the power generating region 4 in the embodiment has a single curved shape, the flexible photovoltaic film module 1 can be directly laid on the power generating region 4, so that after the laying is completed, the flexible photovoltaic film module 1 is bent only in a single direction and does not occur. The three-way stress, therefore, reduces the difficulty of installation to a certain extent, and can also significantly improve the installation effect and prolong the service life.

Third exemplary embodiment

The exemplary embodiment provides a photovoltaic power generation roof including a structural layer in which a central portion of the structural layer is a single curved surface, and a bus bar of the power generating region extends in a left-right direction along a track extending in the front-rear direction. The curve moves to form a single curved surface of the power generation zone. The periphery of the power generation area is a transition zone, and the transition zone is a closed structure. The transition zone includes two second transition zones on the front and rear sides of the power generation zone respectively. The track curve section of the second transition zone extends in the front-rear direction, and the second transition The busbars of the zone are parallel to the busbars of the power generation zone. The transition zone further includes two double-curved first transition zones on the left and right sides of the power generation zone, one end (or the top end) of the bus bar of the first transition zone is tangent to the busbar of the power generation zone, and the trajectory curve section of the first transition zone Parallel to the trajectory curve segment of the power generation zone.

Specifically, in the present exemplary embodiment, the power generation area is a single curved shape, and the two first transition areas are respectively connected to the two curved edges of the power generation area, and the two second transition areas are respectively separated from the power generation area. Straight line edges are connected. The first transition zone has a hyperboloid shape, and an upper edge of one side of the first transition zone is tangent to and connected to the power generating zone, and a lower surface of the first transition zone is adapted to the upper surface of the roof. The second transition zone has a single curved shape, the upper edge of one side of the second transition zone is tangent to and connected to the power generating zone, and the lower surface of the second transition zone is adapted to the upper surface of the roof.

In the present exemplary embodiment, a smooth transition connection between the first transition zone and the second transition zone, a connection between the first transition zone and the second transition zone, and between the first and second transition zones and the power generation zone may be It can be connected by welding, bonding, riveting and bolting, or it can be formed by integral molding such as stamping and casting.

In the power generation area, a flexible photovoltaic film module is directly laid, and the flexible photovoltaic film assembly and the power generation area can be connected by welding, bonding, riveting, etc., and can also be fixed by pressing the strip.

Since the power generation area in the embodiment has a single curved shape, the flexible photovoltaic film assembly can be directly laid on the power generation area, so that after the laying is completed, the flexible photovoltaic film assembly is bent only in a single direction without generating a three-direction stress. Therefore, the installation difficulty is reduced to a certain extent, and the installation effect can be significantly improved, and the service life is prolonged.

Fourth exemplary embodiment

The exemplary embodiment provides a photovoltaic power generation roof including a structural layer, a middle portion of the structural layer is a power generation area, and a power generation area is surrounded by a transition structure of the enclosed structure; the power generation area is a single curved shape, and the power generation area is a bus bar. Extending in the front-rear direction, the trajectory curve of the busbar of the power generation zone extends in the left-right direction. The transition zone comprises two first transition zones respectively on the front and rear sides of the power generation zone, the first transition zone is a hyperboloid shape, the busbar of the first transition zone is parallel to the trajectory curve of the power generation zone, and the trajectory curve of the busbar of the first transition zone The plane in which it is located is parallel to the busbar of the power generation area. The transition zone further includes two second transition zones on the left and right sides of the power generation zone, the second transition zone is a single curved shape, the busbar of the second transition zone is parallel to the busbar of the power generation zone, and the busbar of the second transition zone is The trajectory curve is tangent to the trajectory curve of the power generation zone.

Specifically, in the present exemplary embodiment, the power generation area is a single curved shape, and the two first transition areas are respectively connected to the two curved edges of the power generation area, and the two second transition areas are respectively separated from the power generation area. Straight line edges are connected. The first transition zone has a hyperboloid shape, and an upper edge of one side of the first transition zone is tangent to and connected to the power generating zone, and a lower surface of the first transition zone is adapted to the upper surface of the roof. second The transition zone has a single curved shape, and the upper edge of one side of the second transition zone is tangent to and connected to the power generating zone, and the lower surface of the second transition zone is adapted to the upper surface of the roof.

In the present exemplary embodiment, a smooth transition connection between the first transition zone and the second transition zone, a connection between the first transition zone and the second transition zone, and between the first and second transition zones and the power generation zone may be It can be connected by welding, bonding, riveting and bolting, or it can be formed by integral molding such as stamping and casting.

In the power generation area, a flexible photovoltaic film module is directly laid, and the flexible photovoltaic film assembly and the power generation area can be connected by welding, bonding, riveting, etc., and can also be fixed by pressing the strip.

Since the power generation area in the embodiment has a single curved shape, the flexible photovoltaic film assembly can be directly laid on the power generation area, so that after the laying is completed, the flexible photovoltaic film assembly is bent only in a single direction without generating a three-direction stress. Therefore, the installation difficulty is reduced to a certain extent, and the installation effect can be significantly improved, and the service life is prolonged.

Fifth exemplary embodiment

The exemplary embodiment provides a photovoltaic power generation roof including a structural layer (or a support layer), a middle portion of the structural layer is a power generation area, a periphery is a transition area, and the power generation area is a flat plate shape; and the transition area is included at the front and rear sides of the power generation area. a second transition zone (or a side transition bar) and a first transition zone (or edge transition bar) on the left and right sides of the power generation zone, wherein the first transition zone and the second transition zone are each a single curved shape, wherein the front side The busbar of the second transition zone is parallel to the front edge of the power generation zone. Similarly, the busbar of the second transition zone on the rear side is parallel to the rear edge of the power generation zone, and the busbar of the first transition zone on the left side is parallel to the left edge of the power generation zone. The busbar of the first transition zone on the right side is parallel to the right edge of the power generation zone.

Specifically, in the present exemplary embodiment, the power generation area is in the shape of a flat plate, and the two first transition areas are respectively connected to opposite sides of the power generation area, and the two second transition areas are respectively connected to the other two sides of the power generation area. The first transition zone and the second transition zone each have a single curved shape, a first transition zone and a second transition The busbars of the zones are all parallel to the edges of their corresponding power generation zones, and the lower surfaces of the first transition zone and the second transition zone are adapted to the upper surface of the roof.

In the present exemplary embodiment, a smooth transition connection between the first transition zone and the second transition zone, between the first transition zone and the second transition zone, and between the first transition zone, the second transition zone and the power generation zone The connection method may be connected by welding, bonding, riveting, bolting, or the like, or may be formed by integral molding such as stamping or casting.

In the power generation area, a flexible photovoltaic film module is directly laid, and the flexible photovoltaic film assembly and the power generation area can be connected by welding, bonding, riveting, etc., and can also be fixed by pressing the strip.

Since the power generation area in the exemplary embodiment is in the shape of a flat plate, the flexible photovoltaic film module can be directly laid on the power generation area, so that after the laying is completed, the flexible film element is not strained, and substantially no stress is generated, and therefore, to a certain extent The installation reduces the difficulty of installation, and can also significantly improve the firmness of the installation and prolong the service life.

Sixth exemplary embodiment

As shown in Figures 7-9, the present exemplary embodiment provides a photovoltaic power generation roof comprising a structural layer and a flexible photovoltaic film assembly 1 mounted on the structural layer. The middle portion of the structural layer is provided with a sinking groove (or groove), and the bottom surface 4 of the sinking groove is a single curved surface shape; the bus bar of the single curved surface is a straight line segment extending left and right; the bus bar extends along a front and rear direction The bottom surface 4 track curve segment moves to form the single curved surface. The periphery of the sinking groove is a transition zone, and the transition zone includes a second transition zone 2 at the front and rear ends of the sinker and a first transition zone 3 on the left and right sides of the sinker; the second transition zone 2 is a single curved shape, The busbar of the two transition zone 2 is a straight section parallel to the busbar of the bottom surface of the sinker, and the straight section moves along a track section of the second transition zone 2 extending in the front-rear direction to form the single curved surface. The first transition zone 3 is a single curved panel, and the busbar of the single curved panel is a straight section, and the straight line moves along a trajectory curve section of the first transition zone 3 extending in the front-rear direction to form the single curved panel, the first transition Zone 3 track curve segment corresponding to the sinker The portion is parallel to the bottom surface 4 track curve segment, and the portion of the first transition region 3 track curve segment corresponding to the second transition region 2 is parallel to the second transition region 2 track curve segment.

The connection between the transition zone and the edge of the sinker includes, but is not limited to, welding, bonding, riveting, bolting, etc., of course, the sinking groove and the transition zone may be integrally formed by stamping or the like.

As shown in FIG. 7 to FIG. 9, the flexible photovoltaic film assembly 1 is installed in a sinking groove, and the flexible photovoltaic film assembly 1 is fixed by welding, bonding, riveting or bolt fixing, pressing and pressing.

In order to mount the junction box of the flexible photovoltaic film assembly 1 on the lower surface of the flexible photovoltaic film assembly 1, a through hole is formed in the bottom surface 4 of the sinker, and the junction box is installed in the through hole, so that the flexible photovoltaic film assembly 1 can be ensured. The surface is flat. Of course, it is also possible to punch a small sinking groove in the bottom surface 4 of the sinking groove and install the junction box in the small sinking groove, so that the surface of the flexible photovoltaic film module 1 can be flattened.

The edge of the flexible photovoltaic film module 1 is sealingly connected to the bottom surface 4 of the sink, so that contaminants such as rainwater can be prevented from entering between the bottom surface 4 of the sink and the flexible photovoltaic film assembly 1. In addition, in order to avoid stress variations due to the difference in temperature and shrinkage caused by the structural layer and the flexible photovoltaic film module 1, a gap of 10 mm is left between the flexible photovoltaic film module 1 and the edge of the sinker. In order to avoid the dirt remaining in the void, the void is filled with a sealing material.

In the photovoltaic power generation roof of the exemplary embodiment, a sinking groove is formed in the middle of the structural layer, and then the flexible photovoltaic film assembly 1 is directly installed in the sinking groove, so that neither a large number of components nor a complicated one is required. The process, and its installation process is fast, which can greatly reduce the time and economic costs.

It should be noted that, in the first exemplary embodiment to the fifth exemplary embodiment, as shown in FIGS. 1 to 6, the upper surface of the power generation area of the photovoltaic power generation roof is higher than the upper surface of the transition area, and In the sixth to tenth exemplary embodiments, as shown in FIGS. 7 to 12, the photovoltaic roof The upper surface of the power generation zone is lower than the upper surface of the transition zone. In other words, in the sixth to tenth exemplary embodiments, the power generation regions in the first to fifth exemplary embodiments correspond to the groove bottom surfaces of the grooves provided in the middle of the structural layer, And the upper surface of the flexible photovoltaic film assembly and the upper surface of the transition region smoothly transition.

Seventh exemplary embodiment

As shown in FIG. 10 to FIG. 12, the exemplary embodiment provides a photovoltaic power generation roof, the photovoltaic power generation roof includes a structural layer, and a central portion of the structural layer is provided with a sinking groove, and the bottom surface 4 of the sinking groove is a single curved surface shape. The bus bar of the single curved surface is a straight line segment extending left and right; the bus bar moves along a curved surface segment of the bottom surface 4 extending in the front-rear direction to form the single curved surface. The periphery of the sinking groove is a transition zone, and the transition zone includes a first transition zone 3 at the front and rear ends of the sinker and a second transition zone 2 on the left and right sides of the sinker; the first transition zone 3 is a single curved shape, The busbar of a transition zone 3 is a straight section parallel to the generatrix of the bottom surface of the sinker, and the straight section moves along a track section of the first transition zone 3 extending in the front-rear direction to form the single curved surface. The second transition zone 2 is a hyperboloid shape, and the bus bar of the hyperboloid is a curved section extending in the left-right direction, and the curved section moves along a track segment of the second transition zone 2 extending in the front-rear direction to form the hyperboloid. The portion of the second transition zone 2 trajectory curve segment corresponding to the sinker is parallel to the trajectory curve segment of the bottom surface 4, and the portion of the second transition zone 2 trajectory curve segment corresponding to the first transition zone 3 is parallel to the trajectory curve segment of the first transition zone 3.

Specifically, in the exemplary embodiment, the bottom surface of the sinking groove is a single curved surface, and the two first transition regions are respectively disposed corresponding to two straight edges of the bottom surface of the sinking groove, and the two second transition regions respectively correspond to the bottom surface of the sinking groove The two curved edges are set. The first transition zone has a single curved shape, and the busbar of the first transition zone is parallel to the busbar of the bottom surface of the sinker. The second transition zone has a hyperboloid shape, and the upper edge of one side of the second transition zone is parallel to the curved edge of the bottom surface of the sinker.

The connection between the transition zone and the edge of the sinker includes, but is not limited to, welding, bonding, riveting, bolting, etc., of course, the sinking groove and the transition zone may be performed by stamping or the like. Body molding.

As shown in FIG. 10 to FIG. 12, the flexible photovoltaic film assembly 1 is installed in a sinker, and the flexible photovoltaic film assembly 1 is fixed by welding, bonding, riveting or bolt fixing, pressing and pressing.

In order to mount the junction box of the flexible photovoltaic film assembly 1 on the lower surface of the flexible photovoltaic film assembly 1, a through hole is formed in the bottom surface 4 of the sinker, and the junction box is installed in the through hole, so that the flexible photovoltaic film assembly 1 can be ensured. The surface is flat. Of course, it is also possible to punch a small sinking groove in the bottom surface 4 of the sinking groove and install the junction box in the small sinking groove, so that the surface of the flexible photovoltaic film module 1 can be flattened.

The edge of the flexible photovoltaic film module 1 is sealingly connected to the bottom surface 4 of the sink, so that contaminants such as rainwater can be prevented from entering between the bottom surface 4 of the sink and the flexible photovoltaic film assembly 1. In addition, in order to avoid stress variations due to the difference in temperature and shrinkage caused by the structural layer and the flexible photovoltaic film module 1, a gap of 10 mm is left between the flexible photovoltaic film module 1 and the edge of the sinker. In order to prevent the void from retaining dirt, the void is filled with a sealing material.

In the photovoltaic power generation roof of the exemplary embodiment, a sinking groove is formed in the middle of the structural layer, and then the flexible photovoltaic film assembly 1 is directly installed in the sinking groove, so that neither a large number of components nor a complicated one is required. The process, and its installation process is fast, which can greatly reduce the time and economic costs.

Eighth exemplary embodiment

The present exemplary embodiment provides a photovoltaic power generation roof, and the present exemplary embodiment is different from the sixth exemplary embodiment in that the underside of the sinking groove of the exemplary embodiment is a single curved surface, but the single curved surface The bus bar extends in the front-rear direction, and the bottom track curve extends in the left-right direction. In the exemplary embodiment, the second transition zone at the front and rear ends of the sinker has a single curved shape, and the busbar of the second transition zone is parallel to the busbar of the bottom surface; the first transition zone on the left and right sides of the sinker is a single curved shape. The busbar of the first transition zone is parallel to the busbar of the bottom surface. The connection between the first transition zone and the second transition zone is smoothly transitioned. when However, the second transition zone can also be processed into a hyperboloid shape, the tangent at the top end of the hyperboloid being parallel to the busbar of the bottom surface of the sinker.

Ninth exemplary embodiment

In this embodiment, a photovoltaic power generation roof includes a structural layer, and a sinking groove is disposed in a middle portion of the structural layer, and a bottom surface of the sinking groove is a flat plate shape, and a transition zone is formed around the sinking groove, and the transition zone is included at both ends of the sinking groove. a second transition zone and a first transition zone on the left and right sides of the sinker; wherein the first transition zone and the second transition zone are each a single curved shape, and the busbar of the second transition zone at the front end is parallel to the bottom surface of the sinker The front side edge, likewise, the busbar of the second transition zone at the rear end is parallel to the rear side edge of the bottom surface of the sinker, the busbar of the first transition zone on the left side is parallel to the left edge of the bottom surface of the sinker, and the first transition zone on the right side The busbar is parallel to the right edge of the underside of the sinker.

A flexible photovoltaic film component is installed in the sinking groove, and the photovoltaic film component is fixed by welding, bonding, riveting or bolt fixing, pressing and pressing.

In order to mount the junction box of the flexible photovoltaic film assembly on the lower surface of the flexible photovoltaic film assembly, a through hole is formed in the bottom surface of the sinking groove, and the junction box is installed in the through hole, so that the surface of the flexible photovoltaic film assembly can be flattened. Of course, it is also possible to punch a small sinking groove in the bottom surface of the sinking groove and install the junction box in the small sinking groove, so that the surface of the flexible photovoltaic film module can be flattened.

The edge of the flexible photovoltaic film module is sealingly connected to the bottom surface of the sinking groove, so that contaminants such as rainwater can be prevented from entering between the bottom surface of the sinking groove and the flexible photovoltaic film module. In addition, in order to avoid stress variations due to the difference in temperature and shrinkage caused by the structural layer and the flexible photovoltaic film assembly, a gap of 10 mm is left between the flexible photovoltaic film module and the edge of the sinker. In order to prevent the void from retaining dirt, the void is filled with a sealing material.

In the photovoltaic power generation roof of the exemplary embodiment, a sinking groove is formed in the middle of the structural layer, and then the flexible photovoltaic film assembly is directly installed in the sinking groove, so that a large number of zeros are not required. Parts also do not require cumbersome processes, and the installation process is fast, which can greatly reduce the time and economic costs.

Since the bottom surface of the sink of the present exemplary embodiment is flat-shaped, substantially no stress is generated when the flexible photovoltaic film module is laid thereon, which is advantageous for extending the service life of the flexible photovoltaic film module.

Tenth exemplary embodiment

The exemplary embodiment provides a photovoltaic power generation roof, which comprises a structural layer, wherein the middle of the structural layer is a through groove, and the bottom surface of the through groove has a single curved shape; the left and right sides of the through groove are connected with the transition zone, and the transition The shape of the zone is a single curved shape, the busbar of the single curved surface is parallel to the busbar of the bottom surface of the through slot; the front and rear ends of the transition zone and the through slot are connected with the vehicle body, and the outer edge of the transition zone is connected with the vehicle body, and the flexible photovoltaic The membrane module is mounted in the channel. A slot or a through hole is formed in the bottom surface of the through groove to install the junction box of the flexible photovoltaic film assembly in the through hole. Similarly, the through groove and the transition zone in this embodiment may be connected by welding, bonding, riveting, bolting, or the like, or may be integrally formed by stamping, casting, or the like. The flexible photovoltaic film assembly in this embodiment can also be fixed by welding, bonding, riveting, bolting, pressing, and the like.

In the exemplary embodiment, the bus bar of the bottom surface of the through groove may be installed in the front-rear direction, and at this time, the transition zone is located on the front side and the rear side of the vehicle body.

In this embodiment, the transition zone can also be processed into a hyperboloid shape, and the tangent line at the top end of the hyperboloid bus bar is parallel to the bus bar of the bottom surface of the trough, and the track line of the hyperboloid is parallel to the track line of the bottom surface of the trough.

In this embodiment, the bottom surface of the through groove may also be a flat plate shape. When the bottom surface of the through groove is a flat plate shape, the transition region can only be a single curved surface, and cannot be a hyperbolic surface. When the transition region is on the left side of the through groove, the transition region is The busbar is parallel to the left side of the bottom surface of the trough. Similarly, when the transition zone is in front of, behind, and on the right side of the trough, the busbar of the transition zone is parallel to the front, back, and right sides of the bottom surface of the trough.

The above embodiments are merely preferred embodiments of the present invention, but the scope of protection of the present invention is not limited thereto, and any one of ordinary skill in the art can easily conceive changes within the scope of the present disclosure. Replacement should be covered by the scope of this new model. Therefore, the scope of protection of this new model should be based on the scope of protection defined by the scope of the patent application.

Claims (19)

A photovoltaic power generation roof comprising: a structural layer comprising a flat-plate or single-curved power generation zone and a transition zone disposed around the power generation zone; and a photovoltaic component layer comprising a flexible photovoltaic film component, the flexibility A photovoltaic film assembly is attached to the upper surface of the power generation zone. The photovoltaic power generation vehicle roof according to claim 1, wherein the power generation area is in the shape of a flat plate, and the transition area includes two first transition areas respectively connected to opposite sides of the power generation area and respectively connected to Two second transition zones on the other two sides of the power generation zone; the first transition zone and the second transition zone are all single-curved, and the bus bars of the first transition zone and the second transition zone are respectively corresponding to the power generation The edge of the zone is parallel, and the lower surfaces of the first transition zone and the second transition zone are adapted to the upper surface of the roof. The photovoltaic power generation roof according to claim 1, wherein the power generation zone has a single curved shape, and the transition zone includes two firsts respectively connected to two curved edges of the power generation zone. a transition zone and two second transition zones respectively connected to two straight edges of the power generation zone; the first transition zone has a hyperboloid shape, an upper edge of one side of the first transition zone and the power generation The regions are tangential and connected, the lower surface of the first transition zone is adapted to the upper surface of the roof; the second transition zone has a single curved shape, and the upper edge of one side of the second transition zone is The power generation zone is tangent and connected, and the lower surface of the second transition zone is adapted to the upper surface of the roof. The photovoltaic power generation roof according to claim 3, wherein the busbar of the power generation zone is perpendicular to a front-rear direction of the roof. The photovoltaic power generation roof according to claim 3, wherein the bus bar of the power generation zone is parallel to the front and rear direction of the roof. For example, the photovoltaic power generation roof according to item 2 or item 3 of the patent application, wherein a power transmission area is provided with a through hole or a groove, and a junction box of the flexible photovoltaic film assembly is disposed in the through hole or the groove, and an edge of the junction box is sealed with the through hole or the groove . The photovoltaic roof according to claim 6, wherein the depth of the groove is the same as the thickness of the junction box. The photovoltaic power generation roof of claim 1, wherein the flexible photovoltaic film module is sealingly connected to the power generation zone. The photovoltaic power generation roof according to claim 1, wherein the power generation zone has a single curved shape, and the transition zone includes two firsts respectively connected to two curved edges of the power generation zone. a transition zone and two second transition zones respectively connected to two straight edges of the power generation zone; the first transition zone has a single curved shape, and an upper edge of one side of the first transition zone is The power generation zone is tangent and connected, the lower surface of the first transition zone is adapted to the upper surface of the roof; the second transition zone has a single curved shape, and the upper edge of one side of the second transition zone Tangentially connected to the power generating zone, the lower surface of the second transition zone is adapted to the upper surface of the roof. The photovoltaic power generation roof according to claim 1, wherein the power generation zone is a groove bottom surface of a groove disposed in a middle portion of the structural layer. The photovoltaic roof according to claim 10, wherein the upper surface of the flexible photovoltaic film assembly and the upper surface of the transition region smoothly transition. The photovoltaic power generation vehicle roof according to claim 10, wherein the bottom surface of the groove is a flat plate shape, and the transition region includes two first transition regions respectively corresponding to opposite sides of the bottom surface of the groove and respectively Corresponding to two second transition regions of the other two sides of the bottom surface of the groove, the first transition region and the second transition region are all single-curved, and the bus bars of the first transition region and the second transition region are parallel The corresponding edge on the bottom surface of the groove. The photovoltaic power generation roof according to claim 10, wherein the groove bottom surface has a single curved shape, and the transition region includes two curved edge portions respectively corresponding to the bottom surface of the groove. Two first transition zones and two second transition zones respectively disposed corresponding to two straight edges of the bottom surface of the groove; the first transition zone has a hyperboloid shape, one side of the first transition zone The upper edge is parallel to the curved edge of the bottom surface of the groove; the second transition region has a single curved shape, and the bus bar of the second transition region is parallel to the bus bar of the bottom surface of the groove. The photovoltaic power generation roof according to claim 13, wherein the bus bar of the bottom surface of the groove is parallel to the front and rear direction of the roof. The photovoltaic power generation roof according to claim 13, wherein the bus bar of the bottom surface of the groove is perpendicular to the front and rear direction of the roof. The photovoltaic power generation roof according to claim 10, wherein the bottom surface of the groove is provided with a through hole or a sinking groove, and a junction box of the flexible photovoltaic film assembly is disposed in the through hole or the sinking groove. The photovoltaic power generation roof of claim 10, wherein the flexible photovoltaic film assembly has a distance from a side of the groove of not more than 10 mm. The photovoltaic power generation vehicle roof of claim 10, wherein the flexible photovoltaic film module is sealingly connected to the bottom surface or the side surface of the groove at least at an edge, the flexible photovoltaic film assembly and the groove side The sealing material is filled between them. The photovoltaic power generation roof according to claim 10, wherein the groove is a through groove, and both ends of the opening of the through groove are connected with a vehicle body, and both sides of the closed groove are connected with the transition zone. The bottom surface of the through groove is a flat shape or a single curved shape.